Machine tool



y 19 J. DAUGHERTY ETAL 2,682,697

MACHINE TOOL Filed Dec. 5, 1947 9 Sheets-Sheet l BY WALTER B. P1 167011 r if M @A rry July 6, 1954 J. DAUGHERTY ETAL 2,682,697

' MACHINE TOOL Filed Dec. 5, 1947 9 Sheets-Sheet 2 July 6, 1954 J. DAUGHERTY ET AL MACHINE TOOL Filed Dec. 5, 1947 9 Sheets-Sheet 3 IN V EN TOR. J1: as]; 21; UHKER 7') BY MITRE .B. Mara y 1954 J. DAUGHERTY ETAL 2,682,697

MACHINE TOOL Filed 5. 947 9 Sheets-Sheet 4 Tgjl July 6, 1954 J. DAUGHERTY ET AL 2,632,697

MACHINE TOOL Filed Dec. 5, 1947 9 Sheets-Sheet 5 J. DAUGHERTY ET AL July 6, 1954 MACHINE TOOL 9 Sheets-Sheet 6 Filed Dec. 5. 1947 HllllllHll JNVENTOR. Jzssz' .DAZM'HERT] 14/22.; TEE B. Mam Y July 6, 1954 Filed Dec. 5, 1947 J. DAUGHERTY ETAL MACHINE TOOL 9 Sheets-Sheet 7 z 01/ Lazy VE r1 $1 I N V EN TOR. Jam's D12 F6HEF T y MLTEB l3 11 167011! Z WM A my.

July 6, 1954 J. DAUGHERTY ET AL MACHINE TOOL 9 Sheets-Sheet 8 Filed Dec. 5, 1947 Amy y 6, 1954 J- DAUGHERTY ETAL 2,682,697

MACHINE TOOL Filed Dec. 5, 1947 9 s t s 9 INVENTOR. JESSE 3.0063753 y By MLYER 6. Mam/Y M E W g y Patented July 6, 1954 MACHINE TOOL Jesse Daugherty and Walter Bernard Wigton,

Cincinnati, Ohio, assignors, by mesne assignments, to Giddings & Lewis Machine Tool Company, Fond du Lac, Wis., a corporation of Wisconsin Application December 5, 1947, SerialNo. 789,998

Claims. 1

This invention relates to improvements in machine tools and particularly to improvements in means for controlling and effecting a cyclic movement of a tool and work piece such, for eX- ample, as in forming, work to a contour as established by a templet or gauge.

Machine tools for performing turning opera-- tions on work pieces to a predetermined contour as established or determined by a templet or gauge are well known but in the past this contouring was eifected at a constant rate of speed and only after the control mechanism and work and tool had been operatively associated with one another. With this type of machine production was limited and the desired finish on the work, at critical points thereon, was likewise limited with the finish not the most desirable. Prior contouring machine tools, as noted above, necessitated substantially a setting up of the machine and work for each successive piece of work even though a large number of duplicate pieces to the same contour was desired and which setting up of the machine required a manual adjustment of the parts. In the event the work and tool, for the operative association of these parts, was effected automatically the normal clearance between the Work and tool, necessary to permit replacement of a finished Work piece by an unfinished one and frequently of considerable distance, was traversed at quite speed of the tool and work. Another difficulty, again as intimated above, was the fact that the feeding rate between the tool and work was substantially constant regardless of the particular portion of the work being formed which resulted in certain portions of the work having a finish other than that necessary so that the work piece had to be subjected toa further machining or tooling operation.

The machine of the present invention overs comes each of these difficulties whereby a more accurate control of the work and tool is effected. a completely automatic machine is provided requiring the user or operator to merely press a starting button or close a starting switch or other pilot device whereupon a cycle of operation of the machine is initiated and the machine completes its operation and stops.

It is, therefore, the principal object of the small rate, at best the maximum cutting present invention to provide a machine tool for providing duplicate contoured work that is automatic in its operation.

Another object of the present invention is the 2. the foregoing object that is adapted to sequentially rapidly adjust the work and tool, feed the work and tool. relative to one another at slow feeding rates, and rapidly retract the tool from the work.

Another object of the present invention is the provision in a machine tool of sequentially operating means for positioning the work and tool relative to one another and effecting a feeding of the tool relative to the work each under separate control means which are independent of one another and interlocked so that when one is operating the other is non-operative.

Another object of the present invention is the provision of means for sequentially effecting the movement of a tool and work relative to one another through angularly related paths and in which said movement through certain paths is at a rapid rate while in other paths is at a slow rate and in which slow rate paths the rate of movement may be adjusted.

The machine tool illustrated in the drawings and to be subsequently described in detail is for completely finishing at one setting a car wheel, that is a wheel of forge steel as employed on rolling stock, such as railroad cars, locomotives, electric street cars, and the like employed on rails, and in which wheels the shape of the tire and flange are important to the proper operation thereof.

It is, therefore, a further and specific object of the present invention to provide an improved machine, a car wheel mill, for producing so called: car wheels.

A still further and specific object of the present invention is the provision of a machine tool for producing turned work pieces in which the periphery of the work piece is turned to a predetermined or preestablished contour and. in which the said work and tool are accurately controlled.

Other objects and advantages of the present invention should be readily apparent by reference to the following specification considered in conjunction with the accompanying drawings forming a part thereof and it is to be understood that any modifications may be made in the exact structural details there shown and described, within the scope of the appended claims, without departing from or exceeding the spirit of the invention.

In the drawings:

Fig. 1 is a front elevation of a machine tool, a car wheel mill, embodying the principles of the present invention.

provision of a machine tool for accomplishing Fig. 2 is a side elevation of the machine of Fig. l as seen particularly from the right-hand. side thereof.

Fig. 3 is an enlarged elevational view of one of the heads of the machine, specifically, the righthand side head.

Fig. 4 is an end elevation of the head of Fig. 3 as seen particularly from the right-hand side of said Fig. 3.

Fig. 5 is a fragmentary sectional view through the head of Fig. 4 taken on line 55 of said Fig. 4.

Fig. 6 is a view similar to Fig. 5 taken in a plane below that of Fig. 5 on line 6-6 on Fig. 4.

Fig. 7 is a fragmentary vertical sectional View through the head taken at right angles to Figs.

. 5 and 6 on line 'l! on Fig. 4.

Fig. 8 is a sectional view taken through a plane just below the plane of the guard of Fig. 4 on line 8-8 on Figs. 3 and 6.

Fig. 9 is an enlarged sectional view through a control mechanism as seen from line 99 on Fig. 3.

Fig. 10 is a sectional view taken at right angles to Fig. 9 on line Ill-l0 on said Fig. 9.

Fig. 11 is a transverse sectional View through the said control mechanism taken on line I l--l I on Fig. 9.

Fig. 12 is a transverse sectional view through the control mechanism taken through a plane ahead of that of Fig. 11 on 1ine iii-12 on Fig. 10.

Fig. 13 is a diagrammatic view showing the paths of movement of the several work heads with respect to the work piece, specifically, a car wheel.

Fig. 14 is an enlarged plan view of the mechanism for effecting automatic cycle of the machine.

Fig. 15 is an enlarged transverse fragmentary sectional view through the control mechanism of Fig. 14 as seen from line 15-45 on Fig. 1.

Fig. 16 is an enlarged fragmentary vertical sectional view through the tool head elevating mechanism as seen from line IEi-l6 on Fig. 1.

Fig. 17 is a transverse sectional view through one of the tool heads ram and saddle as seen from line i'i'--ll on Fig. 3.

Fig. 18 is a wiring diagram showing the con nection of the several tool head control mechanisms with the source 01": current.

Fig. 19 is a wiring diagram of the electric circuits to the main motor and illustrating the interlock with the motors of the several tool heads.

Fig. 20 is an electrical wiring diagram for the control mechanism circuit for the motors of one of the tool heads.

Fig. 21 is an electrical wiring diagram showing the circuits to the motors of one of the heads that effects the rate and direction of rotation of said motors.

Fig. 22 is a longitudinal sectional view of a controlling mechanism as seen from line 22-42 on Fig. 15.

Fig. 23 is a transverse sectional view of the device taken on line 23--23 on said Fig. 22.

Throughout the several views of the drawings similar reference characters are employed to denote the same or similar parts.

As was noted above, the machine illustrated in the drawings and presently to be described in detail is for turning and boring car wheels.

This machine is basically a boring mill well known in the trade and utilized for turning, facing and boring work pieces in which the work is rotating while tools are actuated rela tive thereto in effecting the said operations. It is to be understood however that the control mechanism may be employed with equal facility in machine tools where the work is held stationary and the tools rotated relative thereto as well as in machine tools where no rotation is given either the work or tool such, for example, as a planer, and wherein the work is actuated, though not rotated, relative to the tool and the tool or tools are rotated during the work movement as in a planer milling machine.

Specifically, and referring to the drawings the machine tool comprises a supporting bed 25 having a portion 26 rearwardly projecting and laterally of which projecting portion are uprights 21 and 28 referred to in the trade as side housings. The bed 25 has mounted thereon at its upper end a work supporting chuck 29 having associated therewith movable jaws 30 adapted to engage the work piece 3|. The work piece 3| is illustrated in the drawings as a car wheel having a central hub 32 through which is provided an axle receiving bore 33. The car wheel 3i has a rim or tire portion 34 connected to the hub 32 by a radial flange or web 35. At the rear side of the wheel 3 I, or at the inner circumierence of the tire 3d, there is provided an outwardly projecting flange 36. The rim 34 of the wheel has the web 35 inwardly of its rear edge, as at 31, and it is this portion of the rim that is engaged by the chuck jaws 39 for mounting the wheel in operative position. The said chuck or work holding means forms no part of the present invention except in combination with the tools, said chuck or work holding means forming the subject matter of pending application of Edward W. Kroeger and Jesse Daugherty, Serial No. 732,172, filed March 4, 1947, and entitled Work Holding Means, now Patent No. 2,585,944, issued February 19, 1952.

The chuck jaws 30 are actuated to their clamping and unclamping positions by hydraulically actuated means which is under the control of a manually actuable lever 38 for actuating suitable valves which is clearly disclosed in the above identified Kroeger and Daugherty application.

The table 29 is rotated through suitable gearing connected therewith and driven by a motor 39 having a shaft 40 that enters a housing 4| for driving a motion transmitting train, illustrated in the above identified Kroeger and Daugherty application as a multiple V belt, driving through a power train in the housing extension 26 for efiecting the rotation of the table 29 and work 31 securely clamped thereto.

It might be pointed out, due to the weight of the particular work piece illustrated in the drawings, suitable crane mechanisms are provided for loading and unloading the work on the table 29 which comprises a frame 42 having projecting from the upper corners thereof arms 43 and 44 each of which has a power actuated cable winding and unwinding drum 45 with a hook 46 at the end or each cable.

By this arrangement one of said cranes or power actuated drums 45 may pick up and have in readiness a rough work piece while the piece presently in the machine is being tooled. At the conclusion of the tooling operation the secondcrane or power driven drum 45 may be utilized for removing the said finished work piece from the table and its chuck, and after positioning the unfinished work piece from the first crane or power driven drum, said finished workpiece unloaded during the tooling of said second work piece. This is not new, per se, but contributes to the ease of operating the machine and its increased production.

During a complete cycle of operation of the ma chine, the work piece or car wheel 3| is adapted to have the axle bore 33 formed therethrough, the front face ll of its hub 32 smoothed or finished, the front face it of its rim 36 trued, the angular tread d3 of the rim 34 accurately formed to a predetermined contour or taper, the rear flange 36 accurately formed and rounded and have the front corner of the rim 32, between the face 38 and tread 49, accurately and suitably rounded. In order to accomplish these operations a plurality of tooling heads are employed each of which is automatically actuated through a given cycle of operation and which cycles of operation are diagrammatically illustrated in Fig. 13. In said Fig. 13, the several positions of the tools. are indicated and identified along with the path of movement that they follow from a retracted quiescent position to and through the tooling cycle which includes paths of movement wherein the tools moves rapidly, slowly while effecting a cutting operation, and then rapidly from the work to its initial quiescent position and which latter movement may be through angularly related paths.

The several tools are respectively indicated by the numerals E, 3 and 4 with the said numerals followed by a letter of the alphabet indicating the position of said tools at the beginning and ends of the several paths of movement followed by the tools in which either the direction of tool movement changes or the speed of movement of the tool changes or is adjusted. The several tool heads will now be specifically identified and its construction generally pointed out, following which one of said tool heads will be specifically described along with the control means for that head and a detailed description of the control means for the specifically described head. It is deemed that this method of specifically describing the invention will clearly set forth the complete machine since the said several tool heads and their specific control mechanism are substantially a duplicate of one another.

Referring now to Fig. l the side housing 2'! is provided on its forward face with guides 58 and 5! on which is mounted a tool head indicated in general by the reference numeral 52 and which tool head will be described in detail hereinafter. This tool head 52 carries a tool 53 and which is the tool in Fig. 13 indicated by the numeral l The side housing 2'8, similar to side housing 21, is provided verticall of its face with guides 54 and 55 on which is mounted left-hand side head indicated in general by the reference numeral 563. The side head or tool head 56 is provided with a pair of tools 51 and 58 which are in fixed relation to one another and for all general purposes may be regarded as a single tool. These tools are indicated in the diagram in Fig. 13 by the numeral 3.

Carried by the side housings 2! and 28 near the upper end thereof is a rail 59 provided on its forward face with guides 60 and El. The guides 69 and 51 support a central boring and facing tool head indicated in general by the reference numeral 62. The tool head 62 is provided with a ram 655 in which is mounted for rotation a spindle 6d carrying a pair of tools 65 and 66. The tool 65 is a facing tool for providing the 6 face 47 on the outer end of the hub 3| while the tool 66 is a boring bit for providing the wheel axle bore 33. The tools 65 and E36 of the head 6| are again arranged in a definite relation to one another and ar indicated by the single numeral 4 in Fig. 13.

Mounted on the rail guides 6G and 6! is a sec-- ond tool head indicated in general by the reference numeral 61 and may be designated the right-hand rail head. The tool head 5! is provided with a single tool bit 68 and effects the facing 58 on the wheel rim i i, The tool bit 68 is therefore adapted to traverse the wheel flange 3% from the outer perimeter thereof toward the wheel axis. This tool is indicated in the diagram of Fig. 13 by the numeral 2.

Since the tools of each of the tool heads 52, 5t and iii are adapted to move, in general, substantialh in the direction of the axis of the wheel or work as well as transversely thereof and. since substantially same means are provided in each of these heads it is deemed sufficient if but one of them be described in detail and such a description will be given with respect to the righthand side head 52.

The right-hand side head 52 comprises a saddle 58 having formed therein suitable ways l'ii (Fig. 6) respectively adapted to engage the right-hand housing ways 5% and ti. The saddle 555! projects laterally outwardly of the housing 2? and its way 56 to have secured thereto the means for effecting the translation of said saddle as well as the means for effecting the, translation of the ram as will presently be made clear.

Secured to the saddle is a gear housing H providing bearings 62 and it for a shaft M which has formed integral therewith or secured thereto a worm E5. The shaft ii is suitabl connected as by a sleeve '58 with the shaft ll of a D.-C. motor "it. The motor it is secured to the housing or bracket ii in any suitable or desirable manner such as by attaching legs '59 projecting therefrom. Carried by the motor 5 2 at the outer end thereof is a tachometer is (Fig. 8) connected with and driven by the motor shaft 'i'i.

Within the housing ii is a worm wheel to keyed or otherwise secured to a worm wheel shaft 8! journaled at its inner end in a bearing provided by the housing l! and at its outer end provided by a plate 82 secured to and carried by the housing 'i'i. Outwardly of the housing H and its cover plate 82 the shaft 8! has keyed or other wise secured to it a gear t3 meshing with a pinion 843 journaled on a stud t5 secured to and carried by the housing closure plate 82. The pinion 34 in turn meshes with a gear 85 which has projecting from it a sleeve The gear 88 through its sleeve ill is splined to the outer end 88 or a driven shaft lit. The driven shaft 89 is iournaled in anti-friction bearings 92 and 9! carried by the saddle 59.

The gear sleeve Bl is provided with a circurnferential groove 92 receiving shifter shoe 93 mounted on an arm 94 arranged to be eccentric of a stud 95. rotatably journaled in a plate 95 carried by a gear guard 9! (Fig. i). The stud 95 projects beyond its carrying plate 95 to receive a lever or handle 98 whereby the stud 95 may be rotated or oscillated for effecting a movement of the shifter shoe S3 and thereby a sliding movement of the sleeve 31 and gear. 85 for interrupting the gear train and thereby disconnecting the driving shaft 89 from the motor 18.

The driving shaft 89 extends inwardly toward the vertical axis of the side housing. 21 and. has

keyed or otherwise secured to its inner end a bevel gear 99 meshing with a complementary bevel gear I (Fig. '1) formed integral with or secured to a spur gear I M which in turn is formed integral with or secured to a stud I02. The stud I02 is suitably journaled in anti-friction bearings I03 carried by a rearwardly projecting lug or extension I04 from the saddle 69. The lug or extension I04 is located substantially mid-way of and between the housing guides 50 and 5|.

The said lug or extension I04 of the saddle 69 is further provided with an aperture in the ends of which are mounted anti-friction bearings I05 receiving the reduced end I06 of a lead screw I01. The lead screw I 01 is utilized for raising and lowering the saddle 69 together with the ram carried by said saddle and the said screw I01 has keyed or otherwise secured to its upper end a gear I08 meshing with the compound gear spur pinion ml.

The lead screw I01 depends from the saddle lug or extension I04 and is threadedly received simultaneously by a pair of sleeve nuts I09 and H0 (Fig. 16). The sleeve nut I09 is clamped in position by a clamping cap III which em- 7.

braces the sleeve I09 and is secured to the side housing 21 below the ends of the side housing ways 50 and 5I as by means of suitable bolts I I2, see Fig. 1. The said sleeve nut I09 is provided at its lower end with a radial flange H3 in face abutment with a similar radial flange H4 at the upper end of the sleeve nut I I0. The said flanges I I3 and I I4 are utilized as the means for attaching the sleeve nuts to one another for which purpose bolts II5 are employed to pass through enlarged perforations H5 in the sleeve nut flange I I4 and be threaded into the sleeve nut flange I I3. By this construction, the sleeve nuts may be actuated relative to one another to take up back lash between the said sleeve nuts and lead screw before being secured by the bolts I I5. Secured to and projecting, respectively, from the sleeve nuts I09 and H0 are suitable protecting guard sleeves II6 and H1 in which the screw I01 is encased to protect it from dirt, moisture, and accidental damage.

From the foregoing it will now be appreciated that there has been provided a translating mechanism from the motor 18 to the lead or elevating and lowering screw I01 that is nonadjustable as to speed insofar as use is made of change gears, pick-off gears, or clutches for interposing adjustable speed trains. It should be noted however that the speed of the motor 18 is variable or adjustable from a maximum of 3600 I R. P. M. downwardly whereby the lead or raising and lowering screw I01 may be rotated for effecting the movement of the saddle 69 at rapid traverse rates as well as at slow tooling rates as will later become evident.

The saddle 69 is provided with a guide way I I8 receiving the guiding tongue I I9 of the ram I20. It will be understood that the saddle guide way H8 for the ram I20 is formed at substantially right angles to the saddle guide Way receiving the side housing guides 50 and 5|.

In order to actuate the ram I the saddle 69 has secured to its projecting portion a second bracket or gear box I2I (Fig. 4) which is substantially identical in construction to the gear box 1!. The gear box I2I supplies bearings I22 and I23 (Fig. 5) in which is journaled a shaft I24 having integral therewith or secured thereto a worm I25. The worm I25 is suitably connected, as by a coupling I26. with the shaft I21 of a 11-0. electric motor I28. Any suitable or desirable means may be employed for connecting the motor I28 to the bracket or gear box I2 I, such for example, legs I28. The motor I28, similar to the motor 18 carries at its outermost end a tachometer I28 which has its rotating mechanism connected with the motor shaft I21 to be driven thereby.

Extending transversely of the bracket or gear box I2I is a shaft I30 suitably journaled in bearings provided by said bracket or gear box I2I and a closure plate I3I. The shaft I30 has keyed or otherwise secured to it a worm wheel I32 with which is meshed the worm I25 and the shaft I30 projects forwardly of the gear box supporting and closure plate I3I to have keyed or otherwise secured to its projecting end a gear I32. The gear I32 meshes with a pinion I33 loosely mounted on a stud I34 carried by and outwardly projecting from the plate I3I. The pinion I33 in turn meshes with a gear I35 which has integral therewith a sleeve I36. Through the sleeve I36 the gear I35 is keyed through a splined portion I31 to a driven shaft I38. The driven shaft I38 is suitably journaled in anti-friction bearings I39 and I40 carried by the saddle 69.

The gear sleeve I36 is provided with a circumferential groove I4I adapted to receive a shifter shoe I42 (Fig. 7) carried by an arm I43 at the inner end of a rotatable or oscillatable stud I44. The stud I44 is rotatably mounted in a plate I45 and projects therebeyond to have secured thereto a lever or handle I46 whereby said stud I44 is rotated. The plate I45, similar to the plate 96, is secured to and carried by gear guard 91 all as clearly illustrated in Fig. 8.

The driven shaft I55 has secured thereto, intermediate its ends, and preferably adjacent the bearing I39, a gear I41 which meshes with a pinion I41 which in turn meshes with a gear I48 keyed or otherwise secured to a lead screw I45. The lead screw I49 is provided inwardly of the gear I45 with a reduced portion I50 (Fig. 5) journaled in bearings I5I carried by a transverse or web portion I52 of the saddle 69. The lead screw I49, similar to the screw I01, is threaded into a pair of sleeve nuts I53 and I54. The sleeve nut I53 is provided with a radial flange I55 in face abutment with a similar radial flange I56 on the sleeve nut I54. The sleeve nut flange 55, in addition, is in face abutment with a projecting end or web portion I51 from the ram I20 with said sleeve nuts I53 and I54, through suitable screws or bolts I58, passing therethrough into the web I51, secured to the said projecting end or web portion I51.

From the foregoing it will now be noted that the ram I20 is driven from the motor I28 through a gear train and lead or in and out screw which is quite similar to the gear train between the saddle screw I51 and its actuating motor 13. It will further be noted that the gear train to the ram screw I49 is non-adjustable as to speed said adjustment being obtained by adjusting the speed of rotation of the motor I28 which as will later be made clear is obtained by varying the voltages to the same.

As disclosed in the tooling diagram on Fig. 13 the tool of the right-hand side head moves at a rapid rate from position I-A to I-B whereupon the tool travels downwardly and slightly outwardly for forming the peripheral face or tread of the car wheel. This path of movement is oetween the points I-B and I-C and is effected at a cutting rate which is considerably slower than vIE8.

the rapid traverse rate. Beyond the position I-C the tool travels to the position I-D which is through an arcuate path forming the fillet between the car wheel peripheral face or tread and the radial flange at the back side or end of the wheel. While moving through this arcuate path the tool feed is at a rate less than the feed rate between the positions I-B and l-C. The tool upon reaching the position I-D is rapidly retracted from the work to the position !-E- whereupon the tool is rapidly elevated to its initial. position I-A. In order to cause the tool to follow these'paths there are provided two mechanisms one a sequence control head whose primary function is to change the rate of movement of the tool from rapid traverse to feed and feed to rapid traverse as well as control the direction of rapid traverse while the second control mechanism is a contour head which controls the rate and direction of movement of the tool during the feeding rate of movement.

These control mechanisms are respectively indicated, in general, in the drawings by the reference numeral I59 for the sequence control head and the reference numeral its for the contour control head. Each of these control mechanisms I59 and I6l is carried by the upper end of a bracket IGI (Fig. 3) secured to the ram I29 by any suitable or desirable means, such as bolts I62.

The mounting of the control mechanisms I59 and I60 on the bracket IBI may take any suitable or desirable form, such for example as illustrated in Figs. 3 and 15 wherein use is made of a mounting head I63 secured to the bracket IEiI by bolts I64 in such manner that the said head I63 has a limited amount of adjustment on the bracket I6I. The mounting head IE3 is provided at each end thereof with a split clamping collar 65 and I66 in the former of which is disposed a stud I61 integral with or carried by the housing IE8 of the sequence head or control mechanism i553 while in the latter clamping collar a similar stud His is received projecting from the enclosing housing IIIl of the contour head or control mechanism The split collar I65 is adapted to grip the stud I6? through the medium of a clamping bolt Ill while the split collar I66 is similarly adapted to clamp the stud IE9 through the medium of a bolt I12 The control mechanism or sequence head its, in addition to the housing Ids, is provided sub stantially centrally thereof with a body member H3 which may conveniently be formed integral with the mounting stud I61. The housing member I63 and body member I73 are secured to one another by means oi bolts i'id see Fig. 12. The body member H3 is provided substantially centrally thereof with a bore H and which bore extends from the one end. of the body member inwardly to a point short of the clamping stud I61. Extending into the clamping stud from the bore I15 is a smaller diameter bore H6 having at its inner end a base Ill. The housing main bore Il5 is provided near the ends thereof with bushings I13 and Il'B forming guide bearings for bearing portions I89 and IBI for the sequence head finger 582. The finger I82 is provided between the bearing portions I80 and iii! with an enlarged central portion I83 and is provided beyond the bearing I86 with a reduced stern portion I84 while forwardly of the bearing HiI the finger has a tapered contacting point ltd. In assembly the finger stem portion IM is disposed in the body portion reduced diameter bore I16 and abuts with one end of a coil spring I86 which abuts on its other end with the said reduced bore base I". In practice the spring I86 is maintained under compression.

The body member I73 is provided substantially centrally thereof with a lateral opening Iii'l communicating with the center bore H5. Extending through the said body member lateral bore is an abutment or switch arm I38 secured to the finger central portion I82 as by screws I89, see Figs. 9 and 12.

The body member I13 is substantially rectangular in cross-section and has secured to its upper and lower surfaces pairs of arms I5-I9I and ESE-I523. The arms I so and Isl carry between them a switch I9 3 from which projects a spring biased contactor push button I95 as is usual practice. The arms I92 and I93, likewise, carry between them a switch I95 having projecting from its housing a spring biased push arm or button I571. The switches I96 and ififi are of the usual construction of limit switches which complete electrical circuits on depression of the push buttons I95 and I9! with said circuits being broken on the outward movement thereof by their springs.

In order to protect the said switches I94 and I96 the housing I68, generally cylindrical in cross-section, has its ends closed by suitable end plates I98 and its each of which is held in its closed position, respectively, by a nut 20c and 2526 threaded on to the ends of the body member H3.

With the control device or sequence head in its free or normal position the spring I36 forwardly urges the finger I82 to the position shown in Figs. 9 to 12, inclusive, whereby the abutment or spring arm IE8 is engaging and depressing the push button I95 for closing the switch I94. Upon the finger point I engaging an abutment, as will later be made clear, the said finger is inwardly, axially moved for opening the switch 94 and in certain conditions is retained in the position where both the switches :9 and I are open while in other circumstances the finger it? is sufiiciently inwardly axially moved to cause the abutment or switch arm I83 to engage the button I9? and thereby close the switch not. These switches control and operate control mechanisms for effecting and operating the saddle motor 18 and ram motor I28.

The control device or contour head 3E9 illustrated in detail in Figs. 22 and 23 has at one end of its housing no a body member 2% from which projects the clamping stud I69. Carried by the body member 283 are four electromagnets 2M, 2&5, 285 and 253'! each of which is mounted for adjustment axially of housing Ilt. Any suitable or desirable means may be employed for this purpose such for example as illustrated in Fig. 22 comprising a threaded bolt 28% rotatably secured to each magnet and receiving an adjusting nut 28s for retracting each magnet relative to a coil spring 2 It that determines the ultimate forward position of the magnet.

Carried by the housing no at its other end is a diaphragm 2 II provided with a chuck 2 I2 into which is secured one end of a stylus ZIB. Also carried by the diaphragm 2|! is an armature plate 2 I 4 so positioned relative to the housing H0 and magnets ZiE l-ZI, inclusive, as to have therebetween a gap 2 I5.

These parts are so arranged that the diaphragm 2 I I is adapted to be defiected upon deflection of the stylus tit and thereby vary the gap 2 I5 relative to each of the magnets EM-2d? inclusive.

1 1 Depending upon the gap relative to the several magnets depends the rotation of the saddle motor I8 and ram motor I28 as well as depends whether these motors are rotated simultaneously or in dividually, as will later be made clear.

The housing I19 is provided with electrical outlets 2I6 and 2:6 whereby suitable wire connections may be made with respect to the several magnets 204-231, inclusive. In order to prevent over deflection of the diaphragm 2H and the armature 2I4 the body member 203 has projecting from it toward the diaphragm a stop pin 2 I l. The diaphragm 2H and the armature 214 are mounted in operative position by an end closure plate 2I8 through which the diaphragm chuck 2I2 projects to receive the stylus 2I3.

The sequence head finger I82 and the contour head stylus 2I3 are each operated relative to control dogs and a contour plate. This mechanism comprises a, supporting bracket 2I9 (Fig. 15) secured to and depending from a convenient portion of the machine, here shown as the rail 59. The bracket 2I9 is provided in its forward face with a dove tail guide way 220 (Fig. 2) receiving a correspondingly shaped guide 22I inwardly projecting from a slide 222. The slide 222 carries the mechanism for engagement by the sequence head and contour head.

As shown in Figs. 14 and 15 the slide 222 has superimposed thereon a dog plate 223 which in turn, near its inner end, left-hand end in Fig. 14, carries the contour plate 224. outwardly of the contour plate 224 the dog plate 223 has superimposed thereon a lookout or guard plate 225. The contour plate 224, see Fig. 14, has the operative edge 226 formed to the contour or outline to be given the periphery or tread 49 of the car wheel and at the same time is provided, at the bottom thereof, with the portion 221 that determines the fillet between the said tread 49 and car wheel flange 36, while the operative edge 226 has at its upper end an inclined portion 226' for a purpose later to be made clear.

In the specific embodiment of the invention illustrated in this application the contour plate 224 roughs out the tread 49 by the tool or tool bit 53 while accurately forming and finishing the fillet. The tread 49 is finished by the tool 58 of the left-hand side head 56. It should be further noted that the rear surface of the car wheel flange 36 is finished by the tool or bit 58 of said lefthand side head 56. As was noted above the lefthand side head 56 operates in substantially the same manner as the right-hand side head and has substantially the identical control that the right-hand side head utilizes all as is clearly disclosed in Fig. 1.

The lockout plate 225 for convenience is provided with a forward edge 228 which is substantially identical in outline with the operating edge 22622'I of the contour plate 224.

Mounted on the dog plate 223 is a pair of dogs 229 and 230 while mounted on the lookout plate 225 is a pair of dogs 23I and 232. Each of the dogs 229-232, inclusive, has a top surface 233 which lies in the same plane and is utilized for inwardly actuating the sequence head finger to a position for closing the limit switch I96 through the switch arm or abutment I86. The operative surface of the lookout plate 225 is such that the sequence head finger I92 is held in a central position with each switch I94 and I96 open while the face of the dog plate 223 is at such a level that the coil spring I86 urges the finger I82 to the position illustrated in the drawings, namely, the closing of the slide 222'.

ace 2,697

12 the limit switch I94 through the switch arm or abutment I36.

As was noted above the tool head 52 roughs out the wheel tread 49 and finishes the fillet between this tread and the flange 36 through the tool bit 53 carried thereby, while the tool head 56 finishes the tread 49 and finishes the outer surface of the flange 38 and at the same time rounds or breaks the corner between the rim face 48 and the wheel tread 49 through the tool bits 51 and 58 associated with the said tool head 50. From this it will be seen that the operating means for the sequence heads and contour heads of the tool heads 52 and 56 must bear a definite relation to one another and that the dog plates, lockout plates and contour plates must likewise be similarly related. In order to accomplish this the rail 59 carries at its other end a mechanism substantially identical with that above described and including the slide 222 and the parts carried thereby and which parts are indicated by the same reference numeral used above with the addition thereto of a prime From the foregoing it will be appreciated that the tool heads 52 and 56 must bear a definite relation to one another to produce the wheel tread 49 to the desired size and shape and therefore the control mechanisms, particularly the sequence head I59 and the contour head I60 of the tool head 52 must bear a definite relation to the sequence head I59 and contour head I60 of the tool head 56 and must be accurately related. Specifically this relation is established by the adjustment of the dog carrying slides 2'22 and 222.

It is sometimes necessary to adjust these slides, for example, after tool bit wear, in order to clean up the wheel treads should, for some reason, the tread be provided with comparatively shallow blow holes that must be cleaned out and in order to provide the machine with flexibility for producing different size wheels. From this it follows that an adjustment of the slide 222 toward the axis of the wheel or work piece must be followed by a similar adjustment to be given to Any suitable or desirable means may be provided for accomplishing this function that shown in the drawings and presently to be described being preferred.

Accordingly, each of the brackets 2I9 and 2 I9 is provided centrally therethrough with an opening 234 and 234 (Fig. 15). The ends of the brackets 2I9 and 2I9' are respectively provided with bearings or journals 235-436 and 235-236. Rotatably mounted in said journals is a screw shaft 291 having near one end thereof screw threads 23B, right-hand threads for example, and near the other end thereof screw threads 238, for example, left-hand threads. Each of the slides 222 and 222' is respectively provided with a projecting bracket 239 and 239' which brackets are in turn provided at their outer ends, respectively, with a right-hand nut 240 and a left-hand nut MI. The said nuts 240 and MI are respectively in threaded engagement with the threaded portions 238 and 238' of the screw 231. In order to actuate the screw 231 it has pinned or otherwise secured to one end a hand crank or the like 242.

From the foregoing it will be appreciated that rotation of the screw 231 in a given direction will cause the slides 222 and 222' together with the parts carried thereby to be actuated toward or from one another while rotation of said screw 23! in the opposite direction will corresponding- 1y oppositely actuate the said slides 222 and 222.

By this mechanism if the slide 2'22 is actuated toward the work to cause the ram of tool head 52 to move further toward the work center before the depth of its out is reached the ram of the tool head 56 will likewise be actuated toward the center of the work a greater amount than initially set up. By the same token if the slide 222 is outwardly actuated to prevent the ram of tool head 5t from advancing to the previous set position the ram of the tool head 5% will correspondingly be restricted in its approaching movement.

The right-hand rail head El, as not d abov faces the wheel rim at the face 38 requiring merely a traversing movement of its bit 63. at a slow or feed rate without following a path or cam to provide a contoured surface. According- 7 ly the said tool head 6'! is controlled only by a control device which is substantially identical with the sequence head above described and which sequence head is indicated in the drawings by the reference numeral I59". The said sequence head IE9" is carried by a bracket it!" secured to the ram I" of the tool head iii. The control mechanism or sequence head 153" has its finger movable relative to a dog plate 2:13 that is mounted on a portion of the slide 222 so that it maintains its definite fixed relation with respect to the control mechanisms or sequence and contour heads of the tool heads 52 and 56. This construction is believed clearly shown in Fig. 1 with the dog plate 253 of the tool head 61 having shown thereon the dogs, indicated by reference numeral 243 which are similar in all respects to the dogs 229 and 23!], above described, and whose functions are identical in changing direction and rate of movement of the ram lit.

The central tool head 5'2 on the rail 59 has no movable saddle such as is utilized by the tool heads 52, 58 and 6! but merely utilizes a ram 244 which corresponds with the rams 120 of the other tool heads. The ram 251i is adapted to descend at a rapid rate to operatively associate the tool bit [it whereupon its rate of descent is reduced to the usual feeding rate while the tool bit f-ia is effecting the wheelor work bore 33. Upon the completion of the bore the facing bits 85 are in engagement with the wheel hub face 4? for cleaning up and effecting the said facing 61.

with a dwell before being rapidly retracted from the work to the position illustrated in Fig. 1.

In order to effect these movements of the ram .2244 use is made of a motor similar to the above described meters 18 or 128 having a control circuit operable through suitable limit switches or other pilot devices indicated in the drawings by reference numerals 255, 245, 2d? and 248. These limit switches are adapted, respectively, to be closed by dogs 249, 259, 25l and 252 each carried, adjustably, in a dog channel formed in the face of the ram 244. Since the details of the control circuit forms no part of the present invention and is conventional practice it is deemed sufficient that the foregoing descriptionis sufiicient for accomplishing the movement of the ram 244 in providing the bore 33 and wheel hub face 4'5.

The various motors for the tool heads 52, 56, 52 and 6? are each under control of manually operated switches or other pilot devices with said pilot devices located at control stations 253 and 254 respectively mounted near the right and lefthand ends of the rail 59, as seen in Fig. 1. The

In order to eiface any tool marks from the face 47 the ram 244 is provided. in its movement 14 said control stations may be located at other places on the machine or on a suitable support adjacent to but apart from the machine and in fact may be arranged as a pendant carried by the machine as is usual and accepted practice. The various control switches and pilot devices will be specifically identified hereinafter in connection with the description of the control circuit for the right-hand side head 52.

Before specifically describing and pointing out the control circuits for the saddle motor 18 and ram motor I28 it is desired to describe the circuits for supplying the several motors for each tool head with electrical energy as well as the circuit for the work table motor, the circuit for the chuck dogs hydraulic system motor and the circuit for the motor for actuating the lubricating system for the machine; the lubricating system forms no part of the present invention except the interlock between its motor and the other motors utilized in the machine.

Referring to Fig. 18 the power source shown is three phase alternating current connected through a disconnect switch as: with wires LLl, LL2 and LLS which are respectively connected with fuses FUI, FUZ and FU3 serving as short circuit protection for the hydraulic system motor. Extending from the fuses FUI, FUZ and FU3 are respectively lines Li, L2 and L3 that terminate respectively at one side of contacts lOMl, [0M2 and IOMZi of a solenoid switch and which contacts IOIvii, IOM2 and iOMt have respectively extending from their other sides wires that connect with terminals TI, T2 and T3 of the hydraulic system motor 252. Extending respectively from the wires Li and L3 are wires Li I and L3! which terminate on opposite sides of a start and stop switch which includes a normally open stop switch or button 263 and a normally closed stop switch or button 26%. In this line are normally closed safet overload switch contacts OLA! and OLBI under control of overload elements OLA and OLB in the motor feed wires T! and T2. The said Wires Lil and UN, in addition, include a relay switch solenoid coil lOM which upon energization closes the normally open contacts lOMi, 50M! and iOM3 thereby starting the motor rotor 252.

Connected across the start switch 2'53 is a solenoid switch contact lOM l which forms a holding contact for the solenoid coil iOM so that upon release of the start switch 253 to its normally open position the motor 2523 continues to rotate until the stop switch 2% is actuated.

The main current lines LLi, LLZ and LL3 are utilized in various combinations for supplying energy to various step-down transformers for the several motors of the various tool heads as well as energy for operating the control circuits. It is to be understood however that while a plurality of these transformers are disclosed in the draw ings that a single transformer of sufiicient capacity and the proper characteristics may be utilized and eiTect the same results.

Specifically and as shown in Fig. 18 lines LL? and LLB have respectively extending therefrom wires LLII and LL which include safety fuses FU l and FU5 with said lines LLH and LL34 ter minating at opposite ends of transformer primary coils 1P3 i QT and 2P3 I tT. It should be noted that the transformers IP3ii=T and 2P3lsT energize and cooperate with the secondary coil StifiiT which supplies energy to main leads or bus wires 255V and 266, see Fig. 21. The energy supplied by the transformer secondary coil SSIBT and wires 265 and 2% is utilized for controlling the speed or rate of rotation and the direction of rotation of the saddle motor 18 and ram motor I28, and the circuit or circuits disclosed in said Fig. 21 may be termed the motors rotation circuit. In the feed wire or line 266 is a safety fuse 3B5FU and across these wires is a solenoid coil 30IM of a solenoid switch and which solenoid coil 30IM is energized as will later be made clear for closing the contacts of its switch. The energization of the solenoid coil Still i closes contacts MIMI and 30 3M2, Fig. 18, for completing a circuit across the wires LLI I and LL3I for thereby energizing transformer primary coils IP3MT and 2P304T which in turn set up a circuit in the transformer secondary coil SSMT, Fig. 21, for energizing, as will later be pointed out, the ram motor control mechanism indicated in Fig. 21 by the reference numeral 2'51.

Also, connected across the lines or wires 2G5 and 266, Fig. 21, is a solenoid switch solenoid coil 40 IM, similar to the solenoid coil SQIM and to be energized as later pointed out. The energization of the solenoid coil MHM. closes solenoid switch contacts 4mm: and MHMZ associated therewith for completing an electric circuit across the lines LLI I and LL3I for energizing transformer primary coils iP lE lT and 21 49413, Fig. 18. These primary coils in turn energize and effect a current flow through the transformer secondary coil S IMT, Fig. 21, which supplies the current for the saddle motor control mechanism indicated in Fig. 21 by the reference numeral 268.

From the foregoing it will be appreciated that the lines LLII and LLBI supply energy to the right-hand side head operating motors"; and I28 as well as supply the current and voltage which determines, particularly as will be pointed out hereinafter, the rate and direction of rotation of said motors. The motors for the lefthand side head 56, the motors of the right-hand rail head and the motor of the rail boring and facing head are supplied with energy in a similar manner.

Accordingly, main current lines or wires LLI and LL2 have extending therefrom wires LLI2 and LLIS respectively having therein safety fuses FUli and Fill and terminating at opposite ends of transformer primary coils IP5IOT and 2P5iilT which serve the same functions as the transformer primary coils IP3lIlT and 2P3IOT above. Similarly the circuit from the transformer including primary coils IPSIIJT and ZPEiilT together with the secondary coil associated therewith energizes solenoid switch coils which respectively close contacts 5BiMI-5EIIM2 and @EiMl-fifiiflli: for thereby energizing, re spectively, transformer primary coils IP5MT 21. 5041" and iP5ilT2Piiil lT. The circuit supplied from the primary coils 51 5961? and 2P5D4T supply the energy for the ram motor of the tool head 56 while the energy supplied from the primary coils IPiifi lT and ZPSMT supply the energy for the saddle motor of said tool head 56.

A similar circuit including wires LL33 and LL23 from main lines or wires LLB and LL2 having therein safety fuses FUG and FUQ form a circuit including transformer primary coils IP'IIOT and ZP'IIIIT which serve the same purpose with respect to the saddle and ram motors of the tool head 67 as served by the transformer primary coils IPSIUT and 2P3IQT for the same motors of the tool head 52. The circuit from the transformer primary coils IP'EIGT and 2PIIOT energizes a pair of solenoid switches which respec- 16" tively close solenoid switch contacts lIlIMI- 'IUIMZ and 89IMI--8OIM2 for respectively energizing primary coils IPlil iT-2P1MT and IP8MT2P3MT respectively effecting and con trolling the rate and direction of rotation of the saddle and ram motors of the tool head 6?.

Also, extending from the main lines or wires LLB and LL2 are wires LL34 and LL24 each of which respectively includes a safety fuse FUIIJ and FUII with said wires LL34 and LL24 terminating at opposite ends of transformer primary coils IPSIO'I and 2P9i8T. The circuit energized from the primary coils IPQIOT and 2P9II3T in part serves the same function as the circuit from the primary coils IP3IOT and 2P3IBT insofar as supplying energy for the motor rotation circuit for the ram motor of the tool head I32, since this tool head has but a single motor, and, in addition, the circuit from the transformer primary coils IPBIGT and ZPBIOT supplies the energy for the sequence control circult of the motors as determined by the sequence control mechanisms I59. In supplying energy for the ram motor rotation circuit of the tool head 62 the circuit energized by transformer primary coils IPQIOT and 2P9IllT a solenoid switch is energized for closing solenoid switch contacts SIHMI and SUI M2 for thereby completing a circuit across wires or lines LL34 and LL24 for energizing transformer primary coils IPQMT and 2P904T which accomplish, as noted above, the same functions for the ram motor of the tool head 62 as accomplished by the transformer primary coils IP3MT and 2P304T for the ram motor of tool head 52.

In order for the circuit energized by primary coils IP9I GT and 2P9IllT, which is under the control of the sequence control mechanisms or sequence heads I59, I59, etc., there is illustrated in Fig. 20 the transformer secondary coil S9IOT, energized as noted above, by the transformer primary coils IPGIGT and ZPSIET. The ends of the secondary coil SSIIJT are respectively connected by Wires 2G9 and 2'50 to feed wires or lines 255 and 256. The wires or lines 265' and 266' are so designated because they may be continuations of the wires or lines 265 and 266 from the secondary transformer coil S3IOT of Fig. 21 with said lines illustrated as respectively connected with one another as by wires 265a and 26Gb connecting Figs. 20 and 21 with one another. The circuit including the transformer secondary coil SBIEIT is provided with a safety fuse FUIZ.

The feed lines or wires 265 and 266 have connected across them a time delay switch I92M which after a time delay sufficient to warm up the tubes in motor controls 25'! and 253 closes switch contacts I92TR in the ladder or line 2'II which includes in parallel solenoid switches solenoid coils IBBACR and IQGBCR.

The energization of the solenoid coil ISQACR in Fig. 20 closes normally open switch contacts ISEACRI in a feed wire 212, Fig. 21, connecting the line or wire 266 with the motors contouring control device 213 which is under the control of the contour control mechanism or contour head I60 of the tool head 52. It should be here noted that the control circuit for the tool heads 55 has a similar contouring control device operated by its contouring head I60.

Before proceeding further with the control circuits operated by the sequence control device and the contouring control device it is necessary that the tie-in between the lubricating motor and table motor be described. Accordingly, and with reference to Fig. 19, there is provided a pair of main feed lines or wires 214 and 215 extending from a commercial source of direct current although this current may be supplied from a transformer operated in conjunction with the above identified transformers or even a portion of said transformers. Suflice it that the said D.C. lines 214 and 215 are provided across which is the lubricating system motor indicated by the reference numeral 216 and it should be noted that the line 214 has therein a shut-off switch 211. The lubricating system motor 216 is operated by a start button or switch 218 which has one side of its contacts electrically connected with normally closed stop switch or button 219 which in turn has its opposite side connected with one side of normally closed overload switch contacts L! which switch contacts which has its other side connected to a supplementary feed line or wire 214'. The supplementary feed wire or line 21 t is connected through a safety control fuse FUI3 with the main feed line or wire 214. The other side of the normally open lubricating motor starting switch 218 is connected with one end of a solenoid switch solenoid coil 2M which has its other end connected to the supplementary feed line or wire 215'. The line or wire 215 is connected through safety control fusev FUN with the direct current main line or wire 215. From the foregoing it will be seen that the closingof starting switch 218 will complete an electrical circuit in the ladder or line 280 from line 214 through line or wire 2T6, normally closed overload contacts ZOLI, normally closed stop switch 219, normally'open now closed start switch 218, switch solenoid coil 2M and wire or line 215 to D.-C. current main line or wire 275.

The energization of the solenoid coil 2M closes normally open switch contacts ZMI strapped across the starting switch 2'18 to act as a holding circuit for said coil upon release of said starting switch 2'18 and return to its normally open position. The energization of the switch coil 2M also closes normally open contacts 2M2, associated therewith, for completing the circuit in ladder or line 281 which includes the lubricating motor 215 as follows: from main D.-C. current wire or line 214 through overload element 20L, normally open now closed switch contacts 2M3, motor starting resistance 282, motor armature 2'26, motor fields 233 to the direct current main line 2'55. At the same time there is a current flow through wire 23s to a wire 285 which includes solenoid switch solenoid coil A to the main direct current wire or line 215. The energization of the solenoid coil A closes normally open solenoicl switch contacts A-l thereby connecting the wire 285 into the ladder or wire 28! ahead of the motor starting resistance 282 so that the motor operates at its normal speed.

The machine is now in condition for effecting a cyclic operation thereof which may include all of the tool heads or only certain ones thereof depending upon the desires of the operator or the work to be performed. For this reason each control circuit, such as illustrated in Fig. 20, is provided with an on and off switch 286 for connecting it with the entire machine cycle, cutting it out of the machine cycle or conditioning it to operate through its own cycle, and the invention will be further described on the assumption that each of the tool heads is in the complete machine operating cycle and that they have their on and off switch 286 actuated to the closed position, as illustrated in Fig. 20, It is now only necessary to press or close the master cycle switch, indicated in Fig. 20 by the reference numeral 281, and while shown as two separate buttons or switches this is done merely for dual control so that one of said-switches may be located at each control station, above referred to and indicated in the drawings in Fig. 1 at 253 and 254.

The master cycle switch 28? is in a ladder or line 288 and has one side thereof connected with the control circuit main line or wire 26B and therefore the one end of the transformer secondary coil eem'r through the normally open now closed relay switch contacts IBEBCRI, since there contacts were closed upon the closure of contacts IBZTR which energized the switch solenoid coil IBCR. The other side of the master cycle start switch 281 is connected with the control circuit main line or wire 265' through relay switch solenoid coils IMS, EMS and 3M8 and through said wire 265 with the other end of dividually head manually operated switch bridging circuit, on and off, now on, switch 236, normally closed overload contacts 30|OLI and iEHOLl, relay switch solenoid coils I33ACR, ISSBCR and I33CCR, supplementary D.-C. control circuit return line or wire 265", normally closed stop switches 293, and normally open now closed relay switch contacts !M2, closed by mechanism to be presently described, to the control circuit return line or wire 265 and other end of the transformer secondary coil S9 E OT. It should be here noted that the multiplicity of cycle master'stop switches 293 is merely for the purpose of locating stop switches at strategic points on the machine such for example as at each of the control stations 253 and 255 as well as at the main control panel or panels contiguous to or remote from the machine as is usual practice. It will be appreciated that the closing of the switch IMSI was accomplished by the energizing of the solenoid IMS. It should be noted that the overload contacts SUIOLi and t9 EOLI are respectively in the circuits of the ram motor I28 and the saddle motor 18 and are safety devices to protect the said motors.

At the time the direct current circuit, Fig. 19, was turned on through the switch 2'71 ladders or wires 294, 295, 296 and 291, extending between sub-leads or wires 214 and 215', were energized. In the ladder or wire 294 is a normally closed relay switch contact RR! and a relay switch solenoid coil lAR which is energized for a purpose to be later pointed out. The ladder or wire 295 includes a normally closed relay switch contact IAI and a relay switch solenoid coil ZAR which is energized for a purpose later to be made clear. Ladder or wire 296 includes normally closed relay switch contacts 2Al and a relay switch solenoid coil SAR. which is energized for a purpose later to be made clear. The ladder or wire 29'! also has therein a normally closed relay switch contact 3A2 together with a resistance, Res. A, as well as a field accelerating relay switch solenoid coil FF which functions in the work table motor circuit as will presently be made clear. These ladder circuits to 29?, inclusive, are utilized for cutting out the starting resistance and as an interlock between said starting resistance and motor.

At the time of starting the lubricating system motor 276 and energizing the relay switch solenoid coil 2M the work table motor starting circuit through a ladder or wire 2% between the D.-C. current sub-feed wires or lines 2'! and 275 was energized and which starting circuit, see Fig. 19 includes normally open now closed switch contacts 2M2, normally closed now closed overload contacts !OLI, normally closed now closed overload contacts lOLl, normally closed now closed pressure switch contacts under con trol of the hydraulic medium for the table jaws, and which switch contacts are identified as OPS, normally closed now closed pressure switch contacts under the control of the lubricating medium, and which contacts are identified by the reference character OPSI, a pair of manually operable stop switches 298, located respectively at the control stations 253 and 253, a wire 3B0, normally open now closed relay switch contacts IMSZ, a wire Sill, manually operable jog switches 302, respectively located at the control stations 253 and 254, and a relay switch solenoid coil RE. The energization of the solenoid coil RR closes normally open switch contacts RR! which are connected across the wires 3% and 38! and forms a holding circuit for said relay switch solenoid coil RR wherefore the circuit is maintained complete should for some reason the solenoid coil EMS become deenergized and particularly for holding this circuit if the table motor is operated independently of the tool heads lIlO- tors as through the actuation of either one of a pair of manually operated work table motor starting switches 303 which are respectively located at the control stations 2% and 225 1 and which switches 363 are connected across the wires 30% and t t-l for completing the motor startingcircuit when the solenoid coil iMS is deenergized thereby opening normally open switch contacts IMSZl The energization of the relay switch coil RR also closes normally open switch contacts 3R2 for completing a circuit between the wire 3% and the sub-dead 2l5'. This circuit is from the wire 309 through normally open now closed switch contacts R332, sub-ladder or wire 334, connecting wire 3G5, sub-ladder or wire 3%, normally open now closed switch contacts EARL ZARi and tARI, respectively closed by the ladders or wires 2%, 295 and 296 above detailed, and a relay switch coil AM. The energization of the solenoid coil ilvl closes a normally open contact 5M! in the sub-ladder or wire 3134 for thereby establishing a holding circuit for the relay switch coil ilvl upon opening of the contacts lARl, ZARi and 3AR| as will presently appear. It should be appreciated that the energization of the relay switch coil iM takes place almost immediately after the closing of the cycle master start switch 28'1", 20, which closed the interlock relay switch interlock contacts Ill/LS2.

The energization of the relay switch solenoid coil IM effects the starting of the table motor 39 through the energization of the ladder or wire 30? between the D.-C. current main feed lines or wires 27% and 2'15 and which ladder or wire 30'! includes overload element IUL, field acceler- 20 ating relay switch solenoid coil FA, overload re lay solenoid coil IOL, normally open now closed relay switch contacts IlVL'i, armature of the table motor 353, commutating field 3&8, starting resistance motor series field am.

The starting resistance 399 is gradually cut out of the circuit in bringing the table motor 39 to speed and which is not new, per se, in the present application but is under the control of the relay switch operated by the solenoid coil IM. Accordingly normally open now closed contact 1M4 in the ladder or wire 3!! effects a current fiow through normally closed now closed relay switch contacts IARZ and a relay switch solenoid coil IA. The energization'of the coil IA closes normally open switch contacts IA?! which upon closing out out a portion of the starting resistance The energization of the switch solenoid coil IA opened the normally closed contacts IAI in the ladder or wire 25)?) and deenergized relay switch solenoid coil EAR thereby permitting the closing of normally closed relay switch contacts 2AR2 in a sub-ladder or wire 3 l2 and which sub-ladder or wire 3&2 includes relay switch solenoid coil 2A. The closing of the switch contacts ZARZ is delayed suificiently to permit the motor to reach the speed with the portion of the starting resistance controlled by contacts IA? out out, whereupon the energization of the solenoid switch coil 2A closes contacts 2A2 for cutting out a further portion of said starting resistance 3&5. The energization of the solenoid coil 2A opened the normally closed contacts 2Al in ladder circuit 295 for thereby deenergizing relay switch solenoid coil 3AR. The deenergization 0f the solenoid coil 3AR permits the closing of normally closed contacts 3AR2 in sub-ladder or wire M3 and which ladder or wire 3l3 includes a switch solenoid coil 3A. The contacts 3AR2, similar to the contacts 2AR2 are delayed in their closing to permit the motor to accelerate to the point where the additional starting resistance cut out indicates. Upon the final closing of contacts SARZ and energization of the solenoid coil 3A normally open contacts 3A2 are closed thereby completely eliminating from the motor circuit the starting resistance 30%! and permitting the table motor to run at its maximum or desired speed. The energization of the switch solenoid coil (in. also opened normally closed contacts 3Al in the ladder or wire 2%}? thereby energizing the relay switch solenoid coil l fe for cutting out the accelerating resistance.

As shown in Fig. 19 the motor armature and commutating field circuits have connected therearound, as is usual practice, the shunt-field circuit in which is disposed a rheostat SR for determining the rate of rotation of the motor at the speed proper to effect stock removal which depends on the kind of material being machined and the kind of tools used.

It should be noted that there is provided in the wires sec and eat a series of opposed attaching points respectively indicated by reference numerals 3% and Bill which are employed for connecting into the circuit the sequence control circuits of the various tool heads and constitutes an interlock for said heads when they are individually actuated through their cycles upon actuation of a manually operable push button or the like, as will later be pointed out in connection with the tool head 52 here being specifically described.

Associated with each of the control stations and 254 and particularly the portions of said 21 control stations assigned to the respective tooling heads are indicating si nals in the form of lights which indicate the condition of the control circuit and the operation of the tool head taking place. Accordingly, and referring to Fig. 20, the closing of the relay switch IBGBCRI in the wire or line 266 to efiect a flow therethrough and the fiow of current through the circuit including the master cycle start switch 281 effected a current flow through the wire 314 that connects the control circuit main lead 266' with the sub-lead 266 and the sub-lead 266'. This flow of current in the sub-lead 266' is through normally open now closed relay switch contacts IBZCCRZ, closed as will presently be made clear, to a ladder or wire 315 which has therein the signal light RI. The current flows from the ladder or wire 315 through a connecting wire 3H5 to a sub-ladder or wire 3H that extends from ladder or wire 292 and which sub-ladder or wire 3|! has therein a relay switch solenoid coil 1350B. In the ladder or wire 3 I 5 is normally open now closed relay switch contacts I35CR| which acts as a holding contact for the relay switch solenoid coil 135GB in supplying current thereto from the sub-main feed wire 266" when the subfeed wire 286" is deenergized.

The energization of the signal RI indicates that the ram of the tool head 52 is to be actuated or is being actuated toward the work at a rapid rate. At this time the sequence head finger I85 is resting on the dog 229 thereby closing the limit switch I95, which is identified in the wiring diagram of Fig. 20 by the reference character I32LS. At this time the limit switch I94, indicated in the wiring diagram of Fig. 20 by the reference.

character 13 ILS, is open for thereby deenergizing the control relay switches coils 304GB. and 404GB. The closing of the limit switch I32LS in the ladder or wire 3 l8 energized relay switches solenoid coils l32ACR, I32BCR and I32CCR. It is the closing of the solenoid coil l32CCR that closed the normally open contacts I32CCR2 above to energize ladder or wire 3|5. At this time current from the transformer secondary coil S304T, Fig. 21, is supplying current through a plurality of wires to the ram motor control 261 at various voltages through safety fuses 3EHFU, 302FU, 303FU and 384F 11 in certain of which wires are resistances 361R. and 308R. The motor control mechanism 261 is a commercial product produced by electrical equipment control mechanism manuiacturers, such as, The General Electric Company whose product is commercially known as a Constant Current Thymotrol and this control mechanism forms no part of the present invention except in combination. Also connected into the motor control 267 is a wire 319 from the control circuit main lead or wire 26B. Extending from the motor control 261 is a wire 32!! that terminates in the main feed wire or line 265 and which wire has therein normally open now closed relay switch contacts 3B3CRI, previously closed as will presently be explained, fixed resistance 325R and relay switch solenoid coil SMTR. The energization of the solenoid coil 3MTR is delayed by a delayin circuit including wire 320' extendin from wire 32!! and including a fixed resistance 326R. and a condenser 391C. The energization of the solenoid coil 30 ITR closes relay switch contacts 3fllTRl, after a definite time delay, in ladder or wire 32! between control circuit wires 26B and 261. The ladder or wire 32l also includes a relay switch solenoid coil 30IM and it is the energization of this solenoid coil 361M that closes the contacts 30IMI and SMMZ, Fig. 18, for completing the circuit to the motor control mechanism transformer primary coils IP30AT and ZPBMT. mechanism associated with each of the tool heads 56, 62 and El rotation control circuits closes the contacts for their ram motors control mechanisms. The closing of the relay switch contacts 3EIECRI was accomplished by the energization of the relay switch solenoid coil 303GB in Fig. 20. The energization of the said solenoid coil 303GB. was accomplished when the ladder or wire 292 was energized upon the closing of the master start switch 28! and which ladder or wire energized relay switch solenoid coil I33ACR for thereby ClOSll'lg normally open relay switch contacts i33ACRi ahead of said solenoid coil 303GB and also ahead of relay switch solenoid coil 463GB.

The motor control 2M, see Fig. 21, has extending therefrom wires 322 and 323 respectively connected with the opposite terminals of the ram motor armature I28 with said wire 323 having a connection with the ground or return wire 265 of the control circuit; the wire or line 322 may be termed the feed wire on the ram motor armature receiving its current from the control mechanism within the motor control 26'! while the wire 323 is the return wire to the control circuit wire or lead 255 and the motor control mechanism 261. Also extendin from the motor control mechanism 267 is a pair of additional wires 5524 and 325 connected with the shunt and field resistances for supplying current thereto which determines both the direction of rotation as well as the rate of rotation thereof. In the said field circuit is a thyrite resistor indicated by the reference numeral 373B and which thyrite resister is utilized to limit the magnitude of inductive voltage which would develop in the shuntfield circuit and hold the same to a value which would not damage the insulation oi? the motor shunt-field ii the current through the motor field were interrupted suddenly, all as is well known.

The current supplied to the shunt-field circuit 324 and 325 is under control of a wire 326 or 32! each of which enters the motor control mechanism 26'! for completing a circuit whose other side is formed by a wire are from the motor control 2%! and which wire receives current from the mechanism within the motor control 267 with the circuits 3251*325 and 32'i328 having therein resistances that properly proportion the amount of voltage to be used in controlling the ram motor shunt-field circuit 324325.

The motor control device Eel, in effect, places an electrical potential across the lines 325 and 255 with said line 325 being positive and line 255 negative with respect to one another. Similarly, the motor control device 25'! places an electrical potential across the lines 32? and 265 with said line 255 being positive and the line 32? negative with respect to one another. The line 325 has therein resistances tit-R and 3281?. while the line 321 has therein resistances SIQR and 329R with said resistances in the lines 326 balancing the resistances in the line 321. The current or electrical potential in the line 328 is negative or positive with respect to the potential in line 2% depending upon the resistances in the circuits and whether the resistances in line 325 or the line 32? are connected or latched thereto.

At this time and with the circuit set up as above described the energization of the relay It should be noted that a similar 

